Removing non-homogeneous ice from a fuel system

ABSTRACT

The presently disclosed embodiments utilize an ice separator vessel to trap ice particles in a non-homogeneous ice/fuel mixture flowing in a fuel system. A source of heat, such as heated fuel provided to the ice separator vessel, is used to melt at least a portion of the ice particles so that they do not enter the fuel system downstream of the ice separator vessel.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/768,988 filed on Aug. 19, 2015 which is a national stage of andclaims the priority benefit of PCT Application Serial No.PCT/US2014/017697 filed on Feb. 21, 2014, which claims the prioritybenefit of U.S. Patent Application Ser. No. 61/767,388, filed on Feb.21, 2013, the contents each of which are incorporated herein byreference thereto.

TECHNICAL FIELD OF THE DISCLOSURE

The present disclosure generally related to fuel systems and, morespecifically, to systems and methods for removing ice from a fuelsystem.

BACKGROUND OF THE DISCLOSURE

Fuel systems that supply fuel to engines are sometimes required tooperate in extreme environments. For example, fuel systems supplyingfuel to a gas turbine engine on an aircraft are expected to operate athigh altitudes where ambient temperatures are very low. Consequently,the freezing of water and therefore the formation of ice in the liquidfuel is a concern. The performance of the engine will be adverselyaffected if ice entrained in the fuel reaches the engine.

Therefore, systems and methods to remove ice that has formed in a fuelsystem are needed. The presently disclosed embodiments are directed tothis need.

SUMMARY OF THE DISCLOSURE

The presently disclosed embodiments utilize an ice separator vessel totrap ice particles in a non-homogeneous ice/fuel mixture flowing in afuel system. A source of heat, such as heated fuel provided to the iceseparator vessel, is used to melt at least a portion of the iceparticles so that they do not enter the fuel system downstream of theice separator vessel.

In one embodiment, a fuel system is disclosed, comprising: an iceseparator vessel configured to separate ice particles from a firstsupply of fuel comprising a non-homogeneous fuel/ice mixture, and toreceive heat from a source of heat, wherein the heat melts at least aportion of the ice particles in the ice separator vessel.

In another embodiment, a fuel system is disclosed, comprising: an iceseparator vessel configured to separate ice particles from a firstsupply of fuel comprising a non-homogeneous fuel/ice mixture, and toreceive a second supply of fuel, wherein the second supply of fuel meltsat least a portion of the ice particles in the ice separator vessel.

In another embodiment, a fuel system is disclosed, comprising: a firstsupply of first fuel comprising a non-homogeneous fuel/ice mixture at afirst temperature; a vessel including a first vessel input operativelycoupled to the first supply, a second vessel input, and a vessel output,the vessel being operative to substantially separate at least a portionof ice particles from the non-homogeneous fuel/ice mixture such thatfuel may be discharged from the vessel output while said ice particlesremain in the vessel; and a second supply of second fuel at a secondtemperature greater than the first temperature, the second supplyoperatively coupled to the second vessel input; wherein the second fuelapplied to the second vessel input is operative to melt at least aportion of the ice particles within the vessel.

In another embodiment, a method for melting ice in anon-homogeneousfuel/ice mixture in a fuel system is disclosed, the method comprisingthe steps of: a) receiving a first fuel comprising anon-homogeneousfuel/ice mixture at an ice separator vessel, the first fuel having afirst temperature; b) separating at least a portion of ice particlesfrom the non-homogeneous fuel/ice mixture within the ice separatorvessel; and c) melting at least a portion of the ice particles withinthe ice separator vessel.

Other embodiments are also disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

Various features will become apparent to those skilled in the art fromthe following detailed description of the disclosed non-limitingembodiment. The drawings that accompany the detailed description can bebriefly described as follows:

FIG. 1A is a schematic cross-sectional diagram of an embodiment of a gasturbine engine.

FIG. 1B is a schematic diagram of an embodiment of an auxiliary powerunit.

FIG. 2 is a schematic diagram of a portion of a fuel system according toan embodiment.

FIG. 3 is a schematic diagram of a portion of a fuel system according toan embodiment.

FIG. 4 is a process flow diagram of a method according to an embodiment.

An overview of the features, functions and/or configuration of thecomponents depicted in the figures will now be presented. It should beappreciated that not all of the features of the components of the figureare necessarily described. Some of these non-discussed features, as wellas discussed features are inherent from the figure. Other non-discussedfeatures may be inherent in component geometry and/or configuration.

DETAILED DESCRIPTION OF THE DISCLOSED EMBODIMENTS

For the purposes of promoting an understanding of the principles of theinvention, reference will now be made to certain embodiments andspecific language will be used to describe the same. It willnevertheless be understood that no limitation of the scope of theinvention is thereby intended, and alterations and modifications in theillustrated device, and further applications of the principles of theinvention as illustrated therein are herein contemplated as wouldnormally occur to one skilled in the art to which the invention relates.

Although the embodiments disclosed herein may be used with any fuelsystem supplying any type of engine, a gas turbine engine and anauxiliary power unit are used as exemplary, non-limiting embodimentsherein. FIG. 1A illustrates a gas turbine engine 10 of a type normallyprovided for use in a subsonic flight, generally comprising in serialflow communication a fan 12 through which ambient air is propelled, acompressor section 14 for pressurizing the air, a combustor 16 in whichthe compressed air is mixed with fuel and ignited for generating anannular stream of hot combustion gases, and a turbine section 18 forextracting energy from the combustion gases.

FIG. 1B illustrates a gas turbine auxiliary power unit (APU), indicatedgenerally at 20. APU 20 includes a source of inlet air 22, a compressorsection 24 for pressurizing the air, a combustor 26 in which thecompressed air is mixed with fuel and ignited for generating an annularstream of hot combustion gases, and a turbine section 28 for extractingenergy from the combustion gases. A shaft-mounted load compressor 30provides pneumatic power (through bleed control valve 32) for theaircraft in which the APU is mounted, while a gearbox 34 transfers powerfrom the shaft of the APU to other accessories (not shown). Surgecontrol valve 36 maintains stable, surge-free operation of the APU 20.

Fuel systems supplying fuel to gas turbine engines on an aircraft areexpected to operate with very cold fuel temperatures. Most fuel has somewater content, and at these cold fuel temperatures, water absorbed inthe fuel will come out of saturation in the form of ice crystals. Someof these ice crystals are well mixed with the fuel as a homogeneousmixture. However, some of these ice crystals may stick to cold surfaceswithin the fuel tank and the fuel lines leading to the engines, and thensuddenly release themselves in form of ice particles that are notwell-mixed with the fuel and travel in the fuel toward the engine as anon-homogeneous mixture.

Many engines incorporate a fuel oil heat exchanger to increase thetemperature of the fuel, causing melting of ice crystals in thehomogenous state to prevent ice accumulation in the fuel filter and/orother fuel system components. However, these systems are ineffectivewith relatively large quantities of ice particles that may travel in thefuel lines as a non-homogeneous mixture. These ice particles couldpartially or fully prevent fuel flow into the engine fuel systemcomponents such as the fuel pump, fuel oil heat exchanger, etc. This canadversely affect the performance of the engine. The presently disclosedembodiments effectively deal with ice particles in a non-homogeneousmixture in a fuel system.

Referring now to FIG. 2, selected components of one embodiment of a fuelsystem are schematically illustrated and indicated generally at 50. Itwill be appreciated by those skilled in the art that the fuel system maybe configured in a great variety of ways, and that the fuel system 50illustrated in FIG. 2 is but one example. Fuel from a storage container,such as an aircraft fuel tank (not shown) is supplied via fuel supplyline 102. This fuel is introduced into an ice separator vessel 104 at afirst ice separator vessel input 106. The ice separator vessel 104operates to substantially separate the ice particles in anon-homogeneous fuel mixture by any desired means, such as bycentrifugation or settling (since the ice particles are heavier than thefuel), to name just two non-limiting examples. The means used toseparate the ice particles from the fuel are not critical to thepresently disclosed embodiments.

The separated fuel (substantially free from the ice particles inanon-homogeneous mixture) is withdrawn from ice separator vessel output108 and applied to a fuel input 116 of fuel oil heat exchanger 118. Thefuel oil heat exchanger 118 operates to heat the fuel by placing it inclose proximity to warm oil from the engine gearbox sump, or otherconvenient oil source (not shown), which has been heated by passingthrough the engine.

Fuel applied to the fuel input 116 of fuel oil heat exchanger 118 passesthrough heat exchanger coils (not shown) without coming into directcontact with the oil. However, some of the heat of the oil istransferred to the fuel within the fuel oil heat exchanger 118,increasing the temperature of the fuel. Fuel thus heated exits the fueloil heat exchanger 118 at fuel output 132.

The fuel exiting the fuel output 132 of the fuel oil heat exchanger 118is at an elevated temperature. The excess/unburned portion of thisheated fuel may be applied to a second input 162 of the ice separatorvessel 104 in order to elevate the temperature of the fuel within theice separator vessel 104 and thereby contribute to the melting of theice particles trapped within the ice separator vessel 104 that wereseparated from the fuel applied to the first ice separator vessel input106 of the ice separator vessel 104. This continual application ofheated fuel to the ice separator vessel 104 provides thermal energy thatmay be used to melt the ice particles separated by the ice separatorvessel 104, thereby reducing or eliminating the amount ofnon-homogeneous fuel/ice mixture that enters the fuel system downstreamof the ice separator vessel 104. In other embodiments, other heatsources may be used, such as using bleed air from the engine as a heatsource or using an electric heat source, to name just two non-limitingexamples. The heat from these sources may be used to heat the fuel thatis applied to the ice separator vessel 104, or the heat from thesesources may be applied directly to the ice separator vessel 104. Thesource of heat is not critical to the presently disclosed embodiments.

Referring now to FIG. 3, selected components of one embodiment of a fuelsystem are schematically illustrated and indicated generally at 100. Itwill be appreciated by those skilled in the art that the fuel system maybe configured in a great variety of ways, and that the fuel system 100illustrated in FIG. 3 is but one example. Fuel from a storage container,such as an aircraft fuel tank (not shown) is supplied via fuel supplyline 102. This fuel is introduced into an ice separator vessel 104 at afirst ice separator vessel input 106. The ice separator vessel 104operates to substantially separate the ice particles in thenon-homogeneous fuel mixture by any desired means, such as bycentrifugation or settling (since the ice particles are heavier than thefuel), to name just two non-limiting examples. The means used toseparate the ice particles from the fuel are not critical to thepresently disclosed embodiments.

The separated fuel (substantially free from the ice particles inanon-homogeneous mixture) is withdrawn from ice separator vessel output108 by coupling the input 110 of a first stage boost pump 112. Theoutput 114 of the first stage pump 112 is applied to a fuel input 116 offuel oil heat exchanger 118. The fuel oil heat exchanger 118 operates toheat the fuel by placing it in close proximity to warm oil from theengine gearbox sump, or other convenient oil source (not shown), whichhas been heated by passing through the engine. To this end, an oilsupply line 120 from the gearbox sump supplies oil to oil input 122 sothat it may be passed through the heat exchanger coils 124 that formspart of the fuel oil heat exchanger 118. Once the oil passes through theheat exchanger coils 124, it is discharged from the fuel oil heatexchanger oil output 126 and returned back to the gearbox sump (or otherdesired location). A check valve 128 may be provided to limit thepressure of the oil in the heat exchanger 124.

Fuel applied to the fuel input 116 of fuel oil heat exchanger 118 alsopasses through the heat exchanger coils 124 without coming into directcontact with the oil. However, some of the heat of the oil istransferred to the fuel within the fuel oil heat exchanger 118,increasing the temperature of the fuel. A bypass valve 130 may beprovided in order to allow some fuel to bypass the heat exchanger coils124 if the temperature of the fuel exiting the heat exchanger coils 124is above a predetermined temperature. Fuel thus heated exits the fueloil heat exchanger 118 at fuel output 132.

A temperature sensor 134 may be provided to monitor the temperature ofthe fuel exiting the fuel oil heat exchanger 118 to provide a systemcheck that the fuel oil heat exchanger 118 is operating correctly. Forexample, if the fuel discharged from fuel output 132 is below a presettemperature, an indication may be produced to check for properfunctioning of the bypass valve 130 or other portions of the fuel oilheat exchanger 118.

The heated fuel discharged from fuel output 132 may be filtered byapplying the fuel to the input 136 of a filter 138. A check valve 137maybe coupled between the filter input 136 and a filter output 140 toallow fuel to bypass the filter 138 if the pressure difference becomestoo great (for example, if the filter 138 is becoming clogged). Apressure sensor 139 may be coupled in parallel to the check valve 137 inorder to provide a fuel system prognostic/diagnostic indication offilter clogging. The filter output 140 supplies the fuel to an input 142of a second stage pump 144 (such as, for example, a gear pump). Theoutput 146 of the second stage pump 144 may be applied to the input 148of fuel metering valve 150. Fuel metering valve 150 determines how muchof the fuel discharged from the output 146 of second stage pump 144 willbe applied to the engine according to the current fuel needs of theengine, as is known in the art. Output 152 of the fuel metering valve150 therefore discharges fuel at the desired rate into a fuel line 154to the engine (not shown).

The first stage pump 112 and second stage pump 144 normally produce morefuel at output 146 than is needed by the engine because the pumps aresized to be able to supply enough fuel during engine start when the pumpis operating at a much lower speed. For example, the first stage pump112 and second stage pump 144 in an aircraft gas turbine engineapplication may be capable of producing three or more units of fuel perhour when the engine is operating at full speed, even though the enginemay only require one unit of fuel per hour. This excess unburned fuel isnormally returned to the input 110 of a first stage boost pump 112 orthe input 142 of a second stage pump 144.

The fuel at all locations downstream of the fuel oil heat exchanger 118is at an elevated temperature. The excess/unburned portion of thisheated fuel may be applied to a second input 162 of the ice separatorvessel 104 in order to elevate the temperature of the fuel within theice separator vessel 104 and thereby contribute to the melting of theice particles trapped within the ice separator vessel 104 that wereseparated from the fuel applied to the first ice separator vessel input106 of the ice separator vessel 104. In other embodiments, other heatsources may be used, such as using bleed air from the engine as a heatsource or using an electric heat source, to name just two non-limitingexamples. The heat from these sources may be used to heat the fuel thatis applied to the ice separator vessel 104, or the heat from thesesources may be applied directly to the ice separator vessel 104. Thesource of heat is not critical to the presently disclosed embodiments.

In the illustrated embodiment, an input 156 of a pump relief check valve158 is coupled to the output 146 of the second stage pump 144. When thefuel metering valve 150 is commanding fuel at a rate that is less thanthe rate produced by the first stage pump 112 and the second stage pump144, a backpressure will develop, causing the pump relief check valve158 to open. An output 160 of the pump relief check valve 158 is appliedto a second input 162 of the ice separator vessel 104. In otherembodiments, the output 160 of pump relief check valve 158 may simply becoupled to the first ice separator vessel input 106 of ice separatorvessel 104. This continual application of heated fuel to the iceseparator vessel provides thermal energy that may be used to melt theice particles separated by the ice separator vessel 104, therebyreducing or eliminating the amount of non-homogeneous fuel/ice mixturethat enters the fuel system downstream of the ice separator vessel 104.

It will be appreciated from the present disclosure that the heated fuelapplied to the ice separator vessel 104 may be sourced from any location(or from multiple locations) within the fuel system where the fuel has asufficiently elevated temperature, the use of excess heated fuelupstream of the fuel metering valve 150 being illustrated merely as onenon-limiting example.

It will also be appreciated from the present disclosure that the iceseparator vessel 104 may be placed at different locations within thefuel system, and its location prior to the first stage pump 112 isillustrated merely as one non-limiting example. In some embodiments, theice separator vessel 104 may be placed downstream of the first stagepump 112, with the pump 112 pressure pushing fuel through the iceseparator vessel 104 or a secondary pump (not shown) provided to pullfuel from the output 108 of the ice separator vessel 104. In still otherembodiments, the ice separator vessel 104 may form a part of the fueloil heat exchanger 118.

Thus, it will be appreciated that the various embodiments operate toprovide a method 200 as illustrated in FIG. 4 for meltinganon-homogeneous fuel/ice mixture in a fuel system, whereinanon-homogeneous fuel/ice mixture is provided to the ice separatorvessel 104 at block 202, and the non-homogeneous fuel/ice mixture has afirst temperature. At block 204, the ice separator vessel 104 separatesat least a portion of the fuel from the non-homogeneous fuel/ice mixturewithin the ice separator vessel 104. At block 206, second fuel isprovided to the ice separator vessel 104, the second fuel having asecond temperature that is greater than the first temperature, such thatthe second fuel is operative to melt at least a portion of the iceparticles within the ice separator vessel 104. It will be appreciatedfrom the above disclosure that the second fuel may be added to the iceseparator vessel 104 prior to introduction of the non-homogeneousfuel/ice mixture, and in many instances non-homogeneous fuel/ice mixtureand second fuel will be continuously and concurrently added to the iceseparator vessel 104. In other embodiments, heat from a source otherthan the second fuel may be applied to the ice separator vessel 104.

While the invention has been illustrated and described in detail in thedrawings and foregoing description, the same is to be considered asillustrative and not restrictive in character, it being understood thatonly certain embodiments have been shown and described and that allchanges and modifications that come within the spirit of the inventionare desired to be protected.

What is claimed is:
 1. A fuel system comprising: an ice separator vessel configured to separate ice particles from a first supply of fuel comprising a non-homogeneous fuel/ice mixture, the first supply of fuel being supplied to the ice separator vessel by a fuel supply line at a first ice separator vessel input; a first stage pump coupled to an output of the ice separator vessel; a heat exchanger coupled to an output of the first stage pump; a second stage pump coupled to a fuel output of the heat exchanger; a pump relief check valve coupled to an output of the second stage pump, wherein the pump relief check valve provides heated fuel to a second input of the ice separator vessel and wherein the heated fuel is at a temperature greater than the first supply of fuel and the heated fuel melts at least a portion of the ice particles in the ice separator vessel, wherein the heat exchanger is operably coupled to bleed air received from a gas turbine engine and/or wherein the heat exchanger is operably coupled to an electric heat source and wherein the heat exchanger is a fuel oil heat exchanger in a gas turbine engine.
 2. The fuel system of claim 1, wherein the ice separator vessel is configured to separate the ice particles from the non-homogeneous fuel/ice mixture by centrifugation.
 3. The fuel system of claim 1, wherein the ice separator vessel is configured to separate the ice particles from the non-homogeneous fuel/ice mixture by settling.
 4. A fuel system comprising: an ice separator vessel configured to separate ice particles from a first supply of fuel comprising a non-homogeneous fuel/ice mixture, and to receive a second supply of fuel; wherein the second supply of fuel melts at least a portion of the ice particles in the ice separator vessel.
 5. The fuel system of claim 4, wherein: the first supply of fuel is at a first temperature; and the second supply of fuel is at a second temperature greater than the first temperature.
 6. The fuel system of claim 4, wherein the ice separator vessel is configured to separate the ice particles from the non-homogeneous fuel/ice mixture by centrifugation.
 7. The fuel system of claim 4, wherein the ice separator vessel is configured to separate the ice particles from the non-homogeneous fuel/ice mixture by settling.
 8. The fuel system of claim 4, wherein the second supply of fuel is received from a fuel oil heat exchanger in a gas turbine engine.
 9. A fuel system, comprising: a first supply of first fuel comprising anon-homogeneous fuel/ice mixture at a first temperature; a vessel including a first vessel input operatively coupled to the first supply, a second vessel input, and a vessel output, the vessel being operative to substantially separate at least a portion of ice particles from the non-homogeneous fuel/ice mixture such that fuel may be discharged from the vessel output while said ice particles remain in the vessel; and a second supply of second fuel at a second temperature greater than the first temperature, the second supply operatively coupled to the second vessel input; wherein the second fuel applied to the second vessel input is operative to melt at least a portion of the ice particles within the vessel.
 10. A method for melting ice in a non-homogeneous fuel/ice mixture in a fuel system, the method comprising the steps of: a) receiving a first fuel comprising a non-homogeneous fuel/ice mixture at an ice separator vessel, the first fuel having a first temperature; b) separating at least a portion of ice particles from the non-homogeneous fuel/ice mixture within the ice separator vessel; and c) melting at least a portion of the ice particles within the ice separator vessel.
 11. The method of claim 10, wherein step (c) comprises the step of: c) receiving a second fuel at the ice separator vessel, the second fuel having a second temperature greater than the first temperature; wherein the second fuel received at the ice separator vessel is operative to melt at least a portion of the ice particles within the ice separator vessel.
 12. The method of claim of claim 10, wherein step (b) comprises separating at least a portion of ice particles from the non-homogeneous fuel/ice mixture by centrifugation.
 13. The method of claim of claim 10, wherein step (b) comprises separating at least a portion of ice particles from the non-homogeneous fuel/ice mixture by settling.
 14. The method of claim 11, wherein the second fuel is provided by a fuel oil heat exchanger in a gas turbine engine.
 15. The method of claim 10, wherein step (c) comprises melting the at least a portion of the ice particles within the ice separator vessel using bleed air received from a gas turbine engine.
 16. The method of claim 10, wherein step (c) comprises melting the at least a portion of the ice particles within the ice separator vessel using an electric heat source. 